@iucortisvclll_: #martin #viral #xuhuong #typ #haruharu

𝘾(𝙊₂)𝙍𝙏𝙄𝙎♪
𝘾(𝙊₂)𝙍𝙏𝙄𝙎♪
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Sunday 21 June 2026 12:45:12 GMT
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yeutocnhatthegioi
🎀Người đẹp yêu tf 💗👩🏻 :
Ôi giọng nó khàn khàn nó đỉnh vcl😭😭
2026-06-28 11:38:50
779
iucortisvclll_
𝘾(𝙊₂)𝙍𝙏𝙄𝙎♪ :
Phải chi hồi đó không lướt trúng vd này thì giờ đâu dính cảnh tương tư ❤️‍🩹
2026-06-21 13:04:26
215
juhoon.ntak04
🎀Rùa🐢- Kim🍉🎀 :
mê Nhỏ Martin hát bài Haru haru của Bigbang vãiiii
2026-06-28 15:29:05
13
ngocanh22506
𝒏𝒈𝒐̣𝒄 𝒂𝒏𝒉 :
martin hát hay vl
2026-06-29 03:06:09
106
ltt_trang09
thu_trangg :
bài này của ai vậy ạ
2026-06-29 03:49:23
94
baoyen2012
mày im chưa?? :
ủa nhạc này của cô tít hả:((😳😇
2026-07-10 03:13:15
1
_wnt24
iu mấy nhóc cỏ tí :
chất giọng của tin có gì đó rất đặc biệt luôn á t nghe nhỏ hát bài này bửa g mà kh dứt ra được luôn, với cả bài nanchun nhỏ hát trong show này nữa 😭😭
2026-07-01 15:02:16
12
xuebe173
실기 :
ảnh máy tuổi òi mn
2026-07-05 12:54:28
5
c.pho942
Dương Dương là mặt trời nhỏ :
chồng tớ đấy mn ạ,hãnh diện qs
2026-06-29 12:58:04
20
tien.nek101015
Tran Ctiennnnn💗😋🥰 :
ủa khúc đầu là tin hát đúm khum
2026-06-29 14:04:31
7
_ngoctam.19
Ngọc Tâmm 🦊 :
Khúc này Tin nó đưa t vào Cortis đấy mê vãi
2026-07-02 19:32:36
1
thucanh.hahahihi
Aline.22🎀 :
đoạn hát bè hay
2026-06-29 14:07:28
7
ntth100105
Ntt Hiền 🍀 :
M nhả cái tune ra chưa hả Martin 😌
2026-07-01 05:44:05
3
user7449619857785
기분좋게 살자 :
여러사람중에. 제일감정실린같네
2026-07-03 14:11:14
1
nguyen.kim.long8
Kiều lương tin :
xin đăng nhatky ạ
2026-06-30 01:53:53
1
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Graham’s number is an unimaginably massive finite number, made famous in the 1980 Guinness Book of World Records as the largest number ever used in a formal mathematical proof. It serves as an upper bound for a complex problem in Ramsey theory.The ScaleThe human mind cannot fully grasp the magnitude of Graham's number. It is so immense that if you were to write out all of its digits, the entire observable universe lacks enough space to contain them—even if each digit were shrunk down to the size of a single Planck volume.How It’s Written (Knuth's Arrow Notation)Because standard exponents or power towers like \(3^{3^{3^{\dots }}}\) fall woefully short, mathematicians use Knuth's up-arrow notation (where one arrow \(\uparrow \) means standard exponentiation, two \(\uparrow\uparrow\) mean repeated exponentiation, etc.).The number is constructed through a recursive sequence of 64 steps:First, define a base number \(g_1 = 3 \uparrow\uparrow\uparrow\uparrow 3\) (this alone is already an unfathomably large number).Then, define each subsequent number based on the previous step: \(g_{n} = 3 \uparrow^{g_{n-1}} 3\).The 64th iteration in this sequence, \(g_{64}\), is Graham's number.Fun FactsThe Last Digits: Despite its incomprehensible size, mathematicians have determined the exact last digits of Graham's number. The final digit is a 7, and the last ten digits are ...2464195387.The Origin: Ronald Graham discovered it while working on a problem in Ramsey theory concerning hypercubes, where it originally served as an upper bound (though the true answer could theoretically be as small as 11).Not Infinity: Despite being larger than a googolplex and all the particles in the universe combined, Graham's number is still considered infinitely closer to zero than it is to actual infinity.You can read more about the mathematical background on the Wikipedia Graham's number page or watch a visual breakdown on the Numberphile YouTube Channel.(Note: If you were actually thinking of the Graham number used in finance for value investing, that is an entirely different formula calculated as \(\sqrt{22.5\times \text{EPS}\times \text{BVPS}}\) to find a stock's intrinsic fair value).#fyp #Viral #tcc #🍵🌊🌊 #foryou
Graham’s number is an unimaginably massive finite number, made famous in the 1980 Guinness Book of World Records as the largest number ever used in a formal mathematical proof. It serves as an upper bound for a complex problem in Ramsey theory.The ScaleThe human mind cannot fully grasp the magnitude of Graham's number. It is so immense that if you were to write out all of its digits, the entire observable universe lacks enough space to contain them—even if each digit were shrunk down to the size of a single Planck volume.How It’s Written (Knuth's Arrow Notation)Because standard exponents or power towers like \(3^{3^{3^{\dots }}}\) fall woefully short, mathematicians use Knuth's up-arrow notation (where one arrow \(\uparrow \) means standard exponentiation, two \(\uparrow\uparrow\) mean repeated exponentiation, etc.).The number is constructed through a recursive sequence of 64 steps:First, define a base number \(g_1 = 3 \uparrow\uparrow\uparrow\uparrow 3\) (this alone is already an unfathomably large number).Then, define each subsequent number based on the previous step: \(g_{n} = 3 \uparrow^{g_{n-1}} 3\).The 64th iteration in this sequence, \(g_{64}\), is Graham's number.Fun FactsThe Last Digits: Despite its incomprehensible size, mathematicians have determined the exact last digits of Graham's number. The final digit is a 7, and the last ten digits are ...2464195387.The Origin: Ronald Graham discovered it while working on a problem in Ramsey theory concerning hypercubes, where it originally served as an upper bound (though the true answer could theoretically be as small as 11).Not Infinity: Despite being larger than a googolplex and all the particles in the universe combined, Graham's number is still considered infinitely closer to zero than it is to actual infinity.You can read more about the mathematical background on the Wikipedia Graham's number page or watch a visual breakdown on the Numberphile YouTube Channel.(Note: If you were actually thinking of the Graham number used in finance for value investing, that is an entirely different formula calculated as \(\sqrt{22.5\times \text{EPS}\times \text{BVPS}}\) to find a stock's intrinsic fair value).#fyp #Viral #tcc #🍵🌊🌊 #foryou

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